/* ----------------------------------------------------------------------------- * * (c) The GHC Team 1998-2020 * * Hooks for the I/O subsystem(s) that are called from other parts of the RTS. * * There are several different I/O subsystem implementations (aka I/O managers), * for different platforms (notably Windows vs others), and for the threaded vs * non-threaded RTS. These implementations all need hooks into other parts of * the RTS, such as startup/shutdown, the scheduler and other special features. * * To keep things comprehensible, all the hooks used by all the different I/O * subsystem implementations are centralised here. Not all implementations use * all hooks. * * -------------------------------------------------------------------------*/ #include "Rts.h" #include "rts/IOInterface.h" // exported #include "IOManager.h" // RTS internal #include "Capability.h" #include "Schedule.h" #include "RtsFlags.h" #include "RtsUtils.h" #if !defined(mingw32_HOST_OS) && defined(HAVE_SIGNAL_H) #include "posix/Signals.h" #endif #if defined(mingw32_HOST_OS) #include "win32/ThrIOManager.h" #include "win32/AsyncMIO.h" #include "win32/AsyncWinIO.h" #endif /* Allocate and initialise the per-capability CapIOManager that lives in each * Capability. Called early in the RTS initialisation. */ void initCapabilityIOManager(CapIOManager **piomgr) { CapIOManager *iomgr = (CapIOManager *) stgMallocBytes(sizeof(CapIOManager), "initCapabilityIOManager"); #if defined(THREADED_RTS) #if !defined(mingw32_HOST_OS) iomgr->control_fd = -1; #endif #else // !defined(THREADED_RTS) iomgr->blocked_queue_hd = END_TSO_QUEUE; iomgr->blocked_queue_tl = END_TSO_QUEUE; iomgr->sleeping_queue = END_TSO_QUEUE; #endif *piomgr = iomgr; } /* Called late in the RTS initialisation */ void initIOManager(void) { #if defined(THREADED_RTS) /* Posix implementation in posix/Signals.c * Win32 implementation in win32/ThrIOManager.c */ ioManagerStart(); #elif defined(mingw32_HOST_OS) /* Non-threaded Win32 implementation, either the WinIO IOCP implementation, * or the classic implementation. */ if (is_io_mng_native_p()) { startupAsyncWinIO(); } else { startupAsyncIO(); } #else /* The other implementation is the non-threaded Posix select() one. * It does not need any initialisation. */ #endif } /* Called from forkProcess in the child process on the surviving capability. */ void initIOManagerAfterFork(Capability **pcap USED_IF_THREADS_AND_NOT_MINGW32) { #if defined(THREADED_RTS) && !defined(mingw32_HOST_OS) /* Posix implementation in posix/Signals.c * * No non-threaded impl because the non-threaded Posix select() I/O manager * does not need any initialisation. * * No Windows impl since no forking. * * TODO: figure out if it is necessary for the threaded MIO case for the * starting of the IO manager threads to be synchronous. It would be * simpler if it could start them asynchronously and thus not have to * have the pcap as an inout param, that could be modified. In practice it * cannot be modified anyway since in the contexts where it is called * (forkProcess), there is only a single cap available. */ ioManagerStartCap(pcap); #endif } /* Called in the RTS shutdown before the scheduler exits */ void stopIOManager(void) { #if defined(THREADED_RTS) /* Posix implementation in posix/Signals.c * Win32 implementation in win32/ThrIOManager.c */ ioManagerDie(); #endif } /* Called in the RTS shutdown after the scheduler exits */ void exitIOManager(bool wait_threads USED_IF_NOT_THREADS_AND_MINGW32) { #if !defined(THREADED_RTS) && defined(mingw32_HOST_OS) if (is_io_mng_native_p()) { shutdownAsyncWinIO(wait_threads); } else { shutdownAsyncIO(wait_threads); } #endif } /* Wakeup hook: called from the scheduler's wakeUpRts (currently only in * threaded mode). */ void wakeupIOManager(void) { #if defined(THREADED_RTS) /* Posix implementation in posix/Signals.c * Win32 implementation in win32/ThrIOManager.c */ ioManagerWakeup(); #endif } void markCapabilityIOManager(evac_fn evac USED_IF_NOT_THREADS, void *user USED_IF_NOT_THREADS, CapIOManager *iomgr USED_IF_NOT_THREADS) { #if !defined(THREADED_RTS) evac(user, (StgClosure **)(void *)&iomgr->blocked_queue_hd); evac(user, (StgClosure **)(void *)&iomgr->blocked_queue_tl); evac(user, (StgClosure **)(void *)&iomgr->sleeping_queue); #endif } /* Declared in rts/IOInterface.h. Used only by the MIO threaded I/O manager on * Unix platforms. */ #if !defined(mingw32_HOST_OS) void setIOManagerControlFd(uint32_t cap_no USED_IF_THREADS, int fd USED_IF_THREADS) { #if defined(THREADED_RTS) if (cap_no < n_capabilities) { RELAXED_STORE(&capabilities[cap_no]->iomgr->control_fd, fd); } else { errorBelch("warning: setIOManagerControlFd called with illegal capability number."); } #endif } #endif #if !defined(THREADED_RTS) void appendToIOBlockedQueue(StgTSO *tso) { ASSERT(tso->_link == END_TSO_QUEUE); if (MainCapability.iomgr->blocked_queue_hd == END_TSO_QUEUE) { MainCapability.iomgr->blocked_queue_hd = tso; } else { setTSOLink(&MainCapability, MainCapability.iomgr->blocked_queue_tl, tso); } MainCapability.iomgr->blocked_queue_tl = tso; } void insertIntoSleepingQueue(StgTSO *tso, LowResTime target) { StgTSO *prev = NULL; StgTSO *t = MainCapability.iomgr->sleeping_queue; while (t != END_TSO_QUEUE && t->block_info.target < target) { prev = t; t = t->_link; } tso->_link = t; if (prev == NULL) { MainCapability.iomgr->sleeping_queue = tso; } else { setTSOLink(&MainCapability, prev, tso); } } #endif